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Research ArticleComparison between Base Metals and Platinum GroupMetals in Nitrogen, M Codoped TiO2 (M = Fe, Cu, Pd, Os) forPhotocatalytic Removal of an Organic Dye in Water
Alex T. Kuvarega,1 Rui W. M. Krause,2 and Bhekie B. Mamba1
1 Nanotechnology and Water Sustainability Research Unit, College of Engineering, Science and Technology,University of South Africa, Florida Campus, Johannesburg 1709, South Africa
2Department of Chemistry, Rhodes University, P.O. Box 94, Grahamstown 6140, South Africa
Correspondence should be addressed to Bhekie B. Mamba; [email protected]
Received 22 April 2014; Accepted 7 October 2014; Published 27 October 2014
The photocatalytic performance of a number of nonmetal and metal codoped TiO2for the degradation of eosin yellow under
simulated solar radiation was investigated. The synthesised materials were characterised by FTIR, Raman spectroscopy, XRD,DRUV-Vis, SEM, andTEM.TheN,metal codopedTiO
2containing 0.5 wt.% of themetal consistedmainly of the anatase phase, with
a particle size range of 15–28 nm. The particles were largely spherical and shifted the absorption edge well into the visible region.Band gap reduction was more pronounced for the N, PGM codoped TiO
2compared to N, base metal codoped samples. Codoping
led to an enhancement in the photocatalytic activity of the materials for the degradation of eosin yellow. N, Pd codoped TiO2was
the most effective photocatalyst (99.9% dye removal) while N, Cu codoped TiO2showed the least activity (25.5% removal). The
mechanism for the photocatalytic enhancement was proposed on the basis of formation of an electron deficient Schottky barrier atthe semiconductor-metal interface, which acts as an electron sink and thus retards electron-hole recombination. It was shown thatthe ability of the photocatalyst to degrade the dye depends on the nature and type of the metal dopant in the codoped TiO
2system.
1. Introduction
Any large-scale scheme to harvest solar energy for sustainableenvironmental clean-up will most likely include the useof TiO
2, an extensively studied potential candidate for a
wide range of environmental applications, including waterdecontamination. Use of pure TiO
2is hampered by its wide
band gap (3.2 eV) which has limited its photocatalytic usein real life water treatment systems [1, 2]. To address thesechallenges, much effort is being devoted to the manipulationand modification of the TiO
2lattice structure with a view of
utilising the abundant natural sunlight for decontaminatingpolluted water [3]. The effective utilisation of clean, cheap,safe, and abundant solar energy promises to be an excellentoption for tackling global challenges related to environmentalpollution remediation and sustainability [4]. In general,researchers are concentrating on two aspects of TiO
2related
to its performance: enhancing the photocatalytic efficiencyand extending the absorption edge to the visible region [2,5, 6].
Various methods have been reported on improvementof the photoactivity of TiO
2. Among them, doping with
transition metals has proved to be favourable though themetals, in some cases, were found to act as recombinationcentres resulting in reduced photoactivity [2]. The photocat-alytic reactivity of TiO
2is remarkably enhanced by doping
small amounts of base metals such as Fe, Cu, V, Mo, or Niand noble metals such as Pt, Pd, Os, Ir, Ru, or Rh. Dopingwith metals is believed to result in an overlap of the Ti 3dorbitals with the d levels of themetals causing a bathochromiceffect in the absorption band edge of TiO
2. This band gap
shift favours the use of visible light to activate the TiO2
depending on the type of metal dopant and its concentration.The Fermi levels of these metals are also lower than those
Hindawi Publishing CorporationJournal of NanomaterialsVolume 2014, Article ID 962102, 12 pageshttp://dx.doi.org/10.1155/2014/962102
2 Journal of Nanomaterials
of TiO2; therefore, photoexcited electrons can be transferred
from conduction band to metal particles deposited on thesurface of TiO
2. The overall effect is reduction of electron-
hole recombination, resulting in efficient charge separationand higher photocatalytic activities [2, 4]. Optimal loadingof metal must be taken into consideration since high levelsof metal particle deposition might reduce photon absorptionby TiO
2or the metal centres become electron-hole recom-
bination sites, negatively affecting efficiency [7, 8]. Sincenoble metals are scarce and very expensive, more research isneeded to find low cost metals with improved photocatalyticactivity. Base metals such as Fe and Cu have been shownto trap not only electrons but also holes when the impurityenergy levels introduced are near conduction band as wellas the valence band edge of TiO
2[4]. For that reason,
doping of either Fe or Cu ions is recommended as these lowcost metals may show similar or even better enhancementof photocatalytic activity compared to the rather expensivenoble metals that can only trap one type of charge carrier.These base metals may become promising alternative TiO
2
dopants for enhanced photocatalytic water decontaminationapplications. Metal ion dopants such as Fe3+ and Os4+ canpossibly substitute someTi4+ sites within TiO
2lattice because
their ionic radii (0.64 A for Fe3+ and 0.63 A for Os4+) are abit smaller than those of Ti4+ (0.68 A). Such metals are alsofavourable candidates for doping as they can easily attain half-filled electronic configurtions in their most stable ionic states[9]. In contrast, Cu2+ and Pd2+ will most likely be located oninterstitial positions of the lattice rather than directly on Ti4+sites because of their relatively larger ionic sizes (0.72 A forCu2+ A and 0.86 A Pd2+) compared to Ti4+ [10, 11].
The use of anion doping to improve photocatalyticactivity of TiO
2under visible light is increasing. One of the
most promising and widely investigated materials for visiblephotocatalysis is nitrogen doped TiO
2although other anions
such as F, B, C, P, and S have also been found to enhancethe photocatalytic activity of TiO
2in the visible range. Unlike
metals, anions form less likely recombination centres and aretherefore more effective in enhancing the photoactivity [6,12–14]. However, the mechanism behind the photocatalyticenhancement still remains nebulous. Motivated by the pos-itive photocatalytic response realised through nonmetal andmetal doping of TiO
2, strategies aimed at further enhancing
the quantum efficiency of the TiO2-based materials saw the
sprouting of a material engineering technique known ascodoping.This TiO
2modification technique has gained wide
attention in recent years [11, 15–19]. Taking advantage of thepossible synergistic effects on the photocatalytic activity ofthe material, various forms of double metal dopants, doublenonmetal dopants, double metal, nonmetal dopants, andeven tridopants have been introduced on TiO
2[20–23]. The
objective in many of these studies is to advance the mate-rial engineering of TiO
2by altering the optical properties
through specially designing trap sites for both electrons andholes as well as reducing the band gap [24]. Besides shiftingthe absorption edge of TiO
2successfully from the ultraviolet
region to the visible light region, codoping also improves thephysical properties of TiO
2such as specific surface area and
crystallite size whilst prohibiting the anatase to rutile phasetransformation [25]. Liu andGao [11] reported a S,N codopedTiO2photocatalyst which showed better photocatalytic activ-
ity than singly doped S and N TiO2for degradation of
methylene blue solution under visible light. Sakatani et al. [17]successfully synthesised N, Sr codoped TiO
2, for visible light
photocatalytic degradation of acetaldehyde. They observedenhanced activity for the codoped sample among a groupof studied metal ions. Such observations may open up newpossibilities for the development of efficient solar inducedphotocatalytic materials. However, until now, there are onlya few reports on anion, metal codoped TiO
2[17, 18]. There is
still need for fabrication of chemically stable and highly activephotocatalyst that could work in the visible range.
Currently, there are a limited number of reports on com-parative study of environmental applications of nonmetal,platinum group metal codoped TiO
2with nonmetal, base
metal codoped TiO2. The nonmetal, metal codoping of TiO
2
is envisaged to result in a material with excellent photocat-alytic performance compared to singly- or monodoped TiO
2.
This study reports the sol-gel synthesis of (N, Pd) codopedTiO2, (N, Os) codoped TiO
2, (N, Fe) codoped TiO
2, and (N,
Cu) codoped TiO2nanomaterials and comparison of their
photocatalytic activities for degradation of aqueous eosinyellow (EY) dye under simulated solar light. EY was selectedbecause of its stability to photolysis by solar radiation. Itsabsorbance is also not affected by pH changes in the range3–9.
2. Materials and Methods
2.1. Synthesis of N, Os Codoped TiO2. A modified sol-gel
method in which ammonium hydroxide was used as both asource of nitrogen and a hydrolysing reagent was adopted.Briefly, osmium tetroxide, OsO
4(1 g) (Sigma, USA) was
dissolved in 2-propanol (50mL). An appropriate amount ofthis solution was added to a mixture of 2-propanol C
3H8O,
(50mL) (99.8%, Sigma Aldrich, Germany) and titaniumisopropoxide, Ti(OC
3H7)4(10mL) (97%, Sigma Aldrich,
Germany) to give an Os : Ti percentage of 0.5% and thenammonia, NH
3(3mL of 25%) (Merck, Germany) was slowly
added to the isopropoxide/2-propanol solution with vigorousstirring for about half an hour and stirring continued untilthe solution became homogenous.The resulting sol was driedin air at 80∘C for 12 hours and then calcined for 2 hoursin air at 500∘C in an electric furnace. The sample was thencharacterised by various methods.
2.2. Synthesis of N, Pd Codoped TiO2, N, Fe Codoped TiO
2,
and N, Cu Codoped TiO2. A similar procedure was followed
for the other codoped samples with slight variations in thenature of the metal precursor as well as the sequence ofsolution addition. For N, Pd TiO
2, an appropriate amount
of palladium diammine dichloride, Pd(NH3)2Cl2(45% Pd,
PGM Chemicals, RSA) to give a Pd : Ti proportion of 0.5%,was dissolved in 3mL of 25% ammonia, NH
3(Merck,
Germany), prior to addition to the isopropoxide/2-propanolmixture while, for N, Fe TiO
2and N, Cu TiO
2, appropriate
Journal of Nanomaterials 3
amounts of Fe(NO3)2⋅9H2O (>98%, Sigma Aldrich, Ger-
many) and Cu(NO3)2⋅6H2O (99.5%, Merck, Germany) to
give the metal : Ti proportion of 0.5% were dissolved in the2-propanol (50mL) used as a solvent for the isopropoxideprior to addition of the 3mL of 25% ammonia. Samples werethen treated the sameway as for the N, Os codoped TiO
2.The
N doped TiO2sample was prepared by following the same
procedure without the addition of any metal precursors.
2.3. Characterisation. The morphology of the materials wascharacterized by imaging on a field emission scanning elec-tron microscope (NOVA FEI/FIB FE-SEM) equipped withan INCA EDS for elemental analysis and on a transmissionelectron microscope (Tecnai G2 Spirit TEM). Raman spectrawere acquired on a Czerny-Turner micro-Raman spectrom-eter (Perkin Elmer Raman microscope) with excitation laserbeam of wavelength 785 nm equipped with a cooled chargedcoupled device (CCD) detector set at −50∘C and an OlympusBX51M microscope. The beam path was set to 50X andexposure time to 5 seconds during data acquisition. X-raydiffraction (XRD) experiments were conducted to identifythe crystalline phases and estimate particle sizes of thecodoped samples using a Philips PANalytical X’pert X-raydiffractometer, operated at 40 kV and 40mA. Nickel filteredCu K𝛼radiation (𝜆 = 0.15406 nm) was used as the source.
Particle sizes were estimated by applying the Scherrer equa-tion using the full width at half maximum of themost intensepeak. Fourier transform infrared spectroscopy (FTIR) wasused to verify the bond vibrations related to functionalitieson the materials. A Perkin Elmer, Spectrum 100, was usedand samples were thinly mounted in their powder form ona NaCl window sample accessory and a number of spectraaveraged at a resolution of 4 cm−1. Diffuse reflectance datawere obtained on a Shimadzu UV 2450 spectrophotometerequipped with an IRS 240 integrating sphere. BaSO
4was
used as the reflectance standard. Reflectance data were usedto plot Kubelka-Munk and Tauc plots for band gap estima-tions.
2.4. Evaluation of Photocatalytic Activity. The photocatalyticactivities of the materials were measured by the photodegra-dation of eosin yellow (EY) under simulated solar illumina-tion using an AM 1.5 solar simulator (Oriel, Newport) setat an intensity of 1000Wm−2 (1 sun). The solar simulatoris equipped with an Oriel 500W Xenon lamp as a sourceof radiation. A reference cell (Oriel PV system equippedwith a 2 cm × 2 cm monocrystalline silicon photovoltaic celland a Type K thermocouple) was used to set the simulatorirradiance to 1 sun. A portion of the sample (0.1 g) was addedto 100mL of 100 ppm EY solution followed by sonicationfor about 10 minutes. The suspension was then stirred inthe dark for an hour to allow for adsorption-desorptionequilibrium before illumination. Aliquots (3mL) were thensampled every 15 minutes and filtered through a 0.22 𝜇mPVDF membrane filter for 180 minutes. Variations in EYconcentration under illuminationwere thenmonitored usinga ShimadzuUV-2450 spectrophotometer at thewavelength ofmaximum absorption of the dye (517 nm).
4000 3600 3200 2800 2400 2000 1600 1200 800
(e)(d)(c)
(b)
Ti-O
OH
Tran
smitt
ance
(%)
OH
N-O
(a)
Wavenumber (cm−1)
Figure 1: FTIR spectra of (a) P25, (b) N, Pd TiO2, (c) N, Fe TiO
2,
(d) N, Os TiO2, and (e) N, Cu TiO
2.
3. Results and Discussion
Presence of functionalities on the materials was confirmedby FTIR (Figure 1). Peaks at 3340 cm−1 and 1636 cm−1 can beascribed to OH stretching and the OH bending vibrations ofabsorbed water molecules and the surface hydroxyls on theTiO2particles, respectively. These surface hydroxyl groups
play an important role in the photocatalytic process becausethey act as molecule adsorption centres as well as holescavenging sites for the generation of hydroxyl radicals withhigh oxidation capability [26]. The N, Pd TiO
2showed
highly intense vibrations compared to the other samples. Inaddition, there were also peaks at 1120 cm−1 and 1030 cm−1which can be ascribed to the N–O vibrations. Small peakat 2896 cm−1 can be assigned to CH
3and CH
2stretching
vibration, implying that some organic moieties still existedin the sample. The broad peak in the range 750–520 cm−1,observed in all the samples, is due to stretching vibrationof Ti–O. The codoped samples exhibited wider peaks ascompared to pure commercial P25 in the higher wavenumberregion.
Raman spectroscopy is a powerful technique for inves-tigating various phases of crystalline TiO
2or its modified
forms. The technique is capable of elucidating the pho-tocatalyst structural complexity as phase peaks from eachmaterial are clearly separated in frequency and thereforeeasily distinguishable [27]. Four peaks were observed forall the codoped samples at wavenumbers 145, 395, 515, and640 cm−1 and are attributed to the strong 𝐸
𝑔, the medium
strength 𝐵1𝑔, the 𝐴
1𝑔, and an 𝐸
𝑔Raman mode, respectively
(Figure 2). These observations are consistent with reportedfundamental Raman peaks of anatase TiO
2[28]. In contrast,
the rutile phase which consists of weak features at 142 cm−1,320 cm−1, 357 cm−1, and 826 cm−1 and stronger peaks at447 cm−1 and 612 cm−1 could not be clearly detected, thoughsome of the samples were shown, through XRD analysis, tobe containing a small percentage of the rutile phase [29].This can be attributed to the low percentage rutile phase inall the samples. Commercial TiO
80% anatase and 20% rutile. The strong 𝐸𝑔band for N,
Os TiO2is shifted to higher wavenumber value of about
150 cm−1, evidence of substitutional doping of Os on the TiO2
lattice. PdO has two known Raman active modes ascribedto the 𝐵
1𝑔and the 𝐸
𝑔. These modes are assigned to lines
at 651 cm−1 (𝐵1𝑔) and 445 cm−1 (𝐸
𝑔). The highly intense 𝐵
1𝑔
mode is due to scattering from the (001) face and the𝐸𝑔mode
from the (110) face.There is possibility of overlap between thehighly intense anatase 𝐸
𝑔line with the 𝐵
1𝑔of PdO since they
appear in the same wavenumber region. The PdO 𝐸𝑔line is
less intense and could not be detected at low Pd loadings usedin this study.However, XRDanalysis (Figure 3) confirmed thepresence of PdO in the N, Pd codoped sample. No Ramanlines due to individual metals or their oxides were observedin the nitrogen, metal codoped samples. This may proveeven dispersion of the metals on the TiO
2lattice, with no
segregations or clusters. This may also be due to the presenceof the metal dopants in low concentrations on the crystallattice [30].
The XRD patterns of crystalline materials are shown inFigure 3. The peaks at 2𝜃 values of 25.3, 37.8, 48.0, 53.9, 55.1,62.7, 68.8, 70.3, and 75.0∘ can be indexed to (101), (004),(200), (105), (211), (204), (116), (220), and (215) crystal planesof anatase TiO
2, respectively [29]. In addition, characteristic
diffraction peaks at 27.4, 36.1, and 41.2∘ were also observedfor the P25, N, Fe TiO
2, N, Os TiO
2, and N, Cu TiO
2and
are attributed to the (110), (101), and (111) faces of the rutilephases. The rutile peaks were more pronounced for the N,Cu TiO
2indicating a higher percentage of that phase in this
sample. The presence of Pd inhibited the anatase to rutiletransformation as shown by the low rutile percentage (2.7%)in theN, Pd codoped sample.This is ascribed to the formationof defects at the grain boundaries of the TiO
2resulting in
distortion of ordering and consequently suppression of theanatase to rutile transformation.The dispersed PdO particles
20 30 40 50 60 70 80
AAAAAAAA
AA
RRRR
A
Inte
nsity
(a.u
.)
PdO
Comm. TiO2
N, Pd TiO2
N, Fe TiO2
N, Os TiO2
N, Cu TiO2
2𝜃 (deg)
Figure 3: XRD spectra of the different codoped samples.
on the anatase phase (detected by XRD and TEM analyses)inhibited the rutile phase formation.The significant growth ofPdO phase diminished rutile phase proportion in the sampleand this reflects that codoping critically influences TiO
2
phase transformations [31]. All the other codoped samplesshowed an appreciable amount of the rutile phase (> 10%).Notably, no typical diffraction peaks for the nonmetal ormetal dopants were observed in all the samples except a tinypeak at 2𝜃 value of 33.8∘ attributed to the (101) plane of PdOfor the N, Pd TiO
2.
The principal andmost intense anatase peak (101) at 25.3∘was used to determine the average crystallite size of thesamples using the Scherrer equation:
𝑑 =𝑘𝜆
𝐵 cos 𝜃, (1)
where 𝑑 is the crystalline size, 𝜆 is the X-ray wavelength, 𝐵 isthe full width at half maximum of the peak, 𝜃 is the incidentangle, and 𝑘 is a shape factor [27, 32].
The phase composition of samples was calculated usingthe following formula:
𝑋𝐴= [1 +
𝐼𝑅
0.79 (𝐼𝐴)]
−1
, (2)
where 𝑋𝐴is the percentage content of anatase, 𝐼
𝐴is the
intensity of the anatase (101) peak, and 𝐼𝑅is the intensity of
the rutile (110) peak [33]. The calculated crystallite sizes andphase composition of the samples are shown in Table 1. Thepresent PGMs inhibited crystal growth as shown by the smallcrystallite sizes. The PGM codoped samples showed smallerparticle sizes compared to base metal codoped samples.
The effect of doping on the optical properties of thematerials was evaluated by diffuse reflectance UV-Vis spec-troscopy. The presence of different metal dopants signifi-cantly affected the light absorption pattern of the codoped
Journal of Nanomaterials 5
Table 1: Particle size and phase composition of the materials.
samples (Figure 4(a)). All samples were characterised byan intense absorption in the UV region (300–400 nm).This fundamental absorption is associated with an electrontransition from the valence band to the conduction band inTiO2. Doping with nitrogen, base metals or PGMs led to
red shifts in the absorption edge of the materials. The redshift appeared more pronounced for the N, PGM codopedsamples compared to the N, base metal codoped samplesand N doped sample. The red shift in the absorption edgeis due to the formation of intraband gap impurity energylevels between the valence and the conduction band of TiO
2,
narrowing the semiconductor band gap. The red shift in theabsorption edge in the codoped TiO
2can then be attributed
to the charge-transfer transition between the nitrogen p ormetal d electrons and the TiO
2conduction or valence band.
Metal doping has been reported to result in formation ofdopant energy levels within the band gap of TiO
2. Electronic
transitions from the valence band to the dopant level orfrom the dopant level to the conduction band of TiO
2can
lead to a red shift in the absorption band edge [27]. Dopingwith nitrogen increased the absorption intensity of N TiO
2
into the visible spectral region (>400 nm). The absorptioncentred at about 500 nm is mainly due to the N 2p to Ti 3dtransition. N, Cu codoped TiO
2showed an absorption band
centred at 850 nm in addition to an increase of absorptionat 400–550 nm compared to P25. These absorption bandsare attributed to the d-d transitions of Cu. An increase ofabsorption at 350–500 nm with an absorption tail at 500–800 nm was observed in the case of N, Fe codoped TiO
2.
Again, these are attributed to the d-d transition of Fe.Similarly, N, Pd, and N, Os codoped TiO
2also exhibited
increased visible range absorption which can be attributed tod-d transitions. There is possibility of these metals appearingas oxides on the N TiO
2, an observation supported by the
existence of PdO peak in the XRD spectra of N, Pd codopedTiO2[34].
The reflectance data were converted to absorption coef-ficient and Kubelka-Munk plots generated from the data(Figure 4(b)). Presence of TiO
2could be inferred from the
absorption in the UV spectral region because of the largeband gap of 3.2 eV for the anatase phase. Generally, the N,PGM codoped TiO
2showed higher absorption in the lower
UV region (200–250 nm) compared to the other sampleswithN, Pd codoped TiO
2exhibiting the highest absorption while
N, Cu codoped TiO2had the least UV absorption. Solar
radiation is reported to consist of about 5% UV radiation,which is too low to be the main reason for enhancedphotocatalytic activity in codoped TiO
2considering the
Table 2: Optical band gaps of the materials.
Sample Optical band gap (eV)Comm. TiO2 (P25) 3.1N TiO2 2.7N, Pd TiO2 2.1N, Fe TiO2 2.6N, Os TiO2 2.0N, Cu TiO2 2.8
radiation penetration depth or optical thickness in a slurrycontaining about 0.1 g of the material. Therefore, much ofthe photocatalytic enhancement can only be attributed to theabsorption and activation of the material by the low energyvisible light photon flux [35, 36]. Optical filters are often usedto cut off any UV radiation in studies on purely visible lightenhanced photocatalysis. However, in this study, simulatedsolar conditions were intended to mimic the natural solarconditions on a bright sunny day.
Tauc plots were used to estimate the band gaps of thematerials by plotting the Tauc function versus the energy(Figure 4(c)).The absorption coefficient is related to the bandenergy 𝐸
𝑔by the following equation:
(𝛼ℎV) = 𝐴0(ℎV − 𝐸
𝑔)𝑛
, (3)
where ℎV is the photon energy, 𝐸𝑔is the band gap, 𝐴
0
is a parameter associated with the transition probability,and 𝑛 can take the values 1/2, 2, 3/2, and 3 for directallowed, indirect allowed, direct forbidden, and indirectforbidden transitions, respectively [37, 38]. Assuming a directallowed transition for all the samples, band gap energies wereestimated at the point of contact of the [(𝛼ℎV) ∗ ℎV]2 line tothe energy axis and values tabulated (Table 2). N doping andN, metal codoping had an effect on the optical band gaps ofthe materials. N, PGM codoping had a profound effect onthe band gaps, with N, Os TiO
2giving the lowest (2.0 eV)
followed by N, Pd TiO2(2.1 eV). N, base metal codoping, on
the other hand, also led to band gap reductions at 2.6 eV and2.8 eV for N, Fe TiO
2and N, Cu TiO
2, respectively. These
values are lower than those observed for the commercial P25(3.1 eV). Thus, codoping led to shifts in the band gap energytowards longer wavelengths due to the creation of trap levelsbetween the conduction and valence bands of TiO
2. While
PGMs are much more expensive compared to base metals,they are more effective in shifting the absorption edges tothe visible region in codoped TiO
2systems [34]. This can be
attributed to the type of d orbitals participating in electrontransitions (3d for Fe and Cu, 4d for Pd, and 5d for Os).Devi and Kumar reported a direct relationship between bandgap reduction and inverse metal dopant electronegativity.PGMs are electronegative compared to base metals, leadingto higher band gap reductions [31]. Band gap reduction orred shifts in absorption edges is envisaged to improve thevisible light harvesting capability of the material. This is vitalin designing photocatalytic systems where abundant solarradiation may be used to activate the material as opposed tothe more expensive UV sources.
6 Journal of Nanomaterials
200 300 400 500 600 700 800 9000
20
40
60
80
100Re
flect
ance
(%)
Wavelength (nm)
N TiO2
Comm. TiO2
N, Pd TiO2
N, Fe TiO2N, Os TiO2
N, Cu TiO2
(a)
200 250 300 350 400 450 500 550 6000
2
4
6
8
10
12
14
16
Kube
lka-
Mun
k un
its
Wavelength (nm)
N TiO2
Comm. TiO2
N, Pd TiO2
N, Fe TiO2N, Os TiO2
N, Cu TiO2
(b)
1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.40.0
0.2
0.4
0.6
0.8
1.0
Energy (eV)
N TiO2
Comm. TiO2
N, Pd TiO2
N, Fe TiO2N, Os TiO2
N, Cu TiO2
[(𝛼h�)∗h�]2
(eV)
2
(c)
Figure 4: (a) DRUV-Vis spectra, (b) Kubelka-Munk plots, and (c) Tauc plots of the different materials.
The surface morphologies of the samples were exam-ined by SEM (Figure 5). The samples consisted of sphericalaggregates of small particles with rough surfaces. Clusters oragglomerates of the synthesised catalysts were of sizes in therange 5–10𝜇m.Rough estimates from the images showed thatthe average individual size of particles was in the nanorange.
TEM analysis was performed to probe the particle sizesand morphology of the materials (Figure 6). The N, Pdcodoped TiO
2revealed nearly spherical particles with par-
ticle size range of 20–30 nm, in agreement with XRD results(Figure 6(a)). Pd deposits, as PdO, appeared aswell-dispersed
small dots of about 1-2 nm on the TiO2particles. Therefore,
it can be concluded that Pd occupies interstitial positions onthe TiO
2lattice. No particles were observed on the surface
of the other codoped TiO2samples, an indication that the
metals most likely occupy substitutional positions on theTiO2lattice. N, Fe TiO
2consisted of nanoparticles with
elongated and irregular spherical shapes of approximately20 nm (Figure 6(b)). Elongated particles, some with straightedges and rectangular prism morphologies, were observedfor N, Os TiO
2and N, Cu TiO
2and sizes were in the range
15–30 nm (Figures 6(b) and 6(c)).These observations indicate
Journal of Nanomaterials 7
(a) (b)
(c) (d)
Figure 5: SEM images of (a) N, Pd TiO2, (b) N, Fe TiO
2, (c) N, Os TiO
2, and (d) N, Cu TiO
2.
that different metal dopants have different effects on theoverall size and shape of crystallites of the resulting calcinedsamples in N, metal codoped TiO
2.
The photoactivity of the materials was evaluated by rateof disappearance of the dye UV-Vis chromophore responsiblefor the peak at 515 nm. Dye suspensions were subjected to 5minutes of sonication and an hour of continuous stirring toallow for adsorption-desorption equilibrium before illumi-nation. There were variations in the dye adsorption capacityof the materials (Figure 7). There was some correlationbetween the adsorption capabilities of the materials andthe photocatalytic efficiency.The highest adsorption capacity(17.5%) was noted for N, Pd TiO
2which also showed the
highest photoactivity while the lowest capacity (2.5%) for N,Cu TiO
2correlated well with its low activity. Adsorption of
molecules on the surface of the material is determined bythe surface properties of the material such as surface areaporosity and available surface functionalities. Presence ofsurface OH groups on all the materials was confirmed byFTIR studies. The OH groups are favourable adsorption sitesfor the dye molecules containing electronegative groups orbulky functionalities. Photocatalysis is a surface technique sothe target pollutant must first be adsorbed on the surface ofthe material before attack by the free radicals [39]. Therefore,
the greater the number of OH surface functional groups, thegreater the adsorption capability and, consequently, the betterthe photocatalytic activity.
The photocatalytic activity of the materials was investi-gated by monitoring the decrease in concentration of EY atvarious time intervals under simulated solar light illumina-tion (Figure 8(a)).TheN, PGM codoped TiO
2showed higher
photocatalytic efficiency than the N, base metal codopedTiO2.These observations generally correlated closelywith the
corresponding calculated band gap values. Nitrogen dopingresulted in band gap narrowing (2.7 eV) and improved photo-catalytic performance of TiO
2under visible light irradiation
compared to P25 (Table 3). Similar observations were madeby a number of research groups using different synthesismethods and model pollutants [12, 40, 41]. Interestingly,the photocatalytic activity of N, Pd codoped TiO
2was
greatly enhanced with near total dye degradation (99.9%)being realised in about 90mins. This outstanding visiblelight induced photocatalytic activity can be attributed to thesynergistic effect of N and Pd codoping [30]. While nitrogenis an effective dopant for band reduction, PGMs, like Pd andOs used as codopants, lead to further band gap reduction andenhanced activity. Modifying the surface of TiO
2with these
electron-accepting metals that can form a Schottky barrier at
8 Journal of Nanomaterials
(a) (b)
(c) (d)
Figure 6: TEM images of (a) N, Pd TiO2, (b) N, Fe TiO
2, (c) N, Os TiO
2, and (d) N, Cu TiO
2.
Table 3: Percentage dye degradation by the different materials.
Sample EY degradation (%)Comm. TiO2 (P25) 52.6N TiO2 96.3N, Pd TiO2 99.9N, Fe TiO2 68.1N, Os TiO2 91.7N, Cu TiO2 25.5
the metal/TiO2interface means that they can act as electron
sinks and thus retard electron-hole recombination [38, 42].Base metals have also been used as dopants individually
or on as codopants on TiO2. Recently, base metals (Cr, Mn,
Fe, Co, Ni, Cu, and Zn) were used to replace noble metals asTiO2dopants to reduce the overall catalyst production costs.
Fe-doped TiO2was reported to show high dye-degradation
efficiency of 90% and 75% total organic carbon (TOC)removal efficiency of Acid Blue 92 upon UV light irradiation.The incorporation of base metal ions onto the TiO
2lattice
was found to alter or lower the band gap energy and shift
0.0
2.5
5.0
7.5
10.0
12.5
15.0
17.5
EY ad
sorp
tion
(%)
N T
iO2
Com
m. P
25
N, P
d Ti
O2
N, F
e TiO
2
N, O
s TiO
2
N, C
u Ti
O2
Figure 7: Percentage dye adsorption on different materials.
the catalyst absorbance edge closer to the visible region [8].A similar trend was observed for the N, Fe codoped TiO
2
Journal of Nanomaterials 9
0 20 40 60 80 100 120 140 160 1800.0
0.2
0.4
0.6
0.8
1.0
Irradiation time (min)
Comm. P25
N, Pd TiO2
N, Fe TiO2
N, Os TiO2
N, Cu TiO2
N TiO2
C/C
0
(a)
0 20 40 60 80 100 120 140 160 1800
1
2
3
4
5
6
7
Irradiation time (min)
Comm. P25 Ka = 0.00396min−1
N, TiO2 Ka = 0.0141min−1
N, Pd TiO2 Ka = 0.0346min−1
N, Fe TiO2 Ka = 0.0050min−1
N, Os TiO2 Ka = 0.0108min−1
N, Cu TiO2 Ka = 0.0017min−1
ln(C
0/C
)(b)
Figure 8: (a) Photodegradation profile and (b) photodegradation kinetics of the different samples.
where there was appreciable band gap reduction associatedwith some catalytic enhancement. N, Cu TiO
2on the other
hand showed the lowest photoactivity under the same exper-imental conditions. This can be attributed to the lower bandgap reduction effect (2.8 eV) as well as the possibility of thedopants acting as electron-hole recombination centres.
The Langmuir-Hinshelwood (LH) kinetics is the mostcommonly used model for heterogeneous catalytic processesfor the photodegradation of organic contaminants in solu-tion. Application of this model to an ideal batch reactorproduces a simplified expression [38, 43]:
− ln( 𝐶𝐶0
) = 𝑘app𝑡, (4)
where𝐶 is the concentration of themolecule being degraded,𝐶0is the initial concentration of organic molecules being
degraded, 𝑘app is the apparent rate constant, and 𝑡 is theirradiation time. A plot of ln(𝐶
0/𝐶) versus 𝑡will yield a graph
with a slope of 𝑘app (Figure 8(b)).Linearity of the plots suggests that the photodegradation
reaction approximately follows first order kinetics with 𝑘appvalues from 0.0017min−1 to 0.0346min−1. The introductionof nitrogen and palladium onto the TiO
2matrix drastically
increased the rate constant to 0.0346min−1 compared tocommercial P25 TiO
2(0.00396min−1). In comparison, the
other N, PGM codoped sample (N, Os codoped TiO2)
showed a lower rate constant (0.0108min−1) which wasalmost similar to that of N doped TiO
2(0.0141min−1).
Codoping with base metals led to a slight improvementin photoactivity for N, Fe TiO
2(0.0050min−1) and poor
photoactivity and lower photodegradation rate for N, CuTiO2(0.0017min−1) compared to commercial P25.The lower
rates can be attributed to the poor electron trapping capabilityof the base metals compared to PGMs. Low band gap red
shifts led to poor visible light harvesting capacity for the N,base metal codoped TiO
2samples. There are many variables
in the photocatalytic chain of events that can result in lowerdegradation rates; photonsmay not be absorbed but scatteredout of the reactor; photons may be absorbed but fail tocreate an electron/hole pair, especially if the energy of thephoton is close to the energy of band gap; electron/holepairs may not make it to the surface of the particle butinstead recombine inside the particle. PdO is reported asa p-type semiconductor with band gap values from 0.1 to2.7 eV. Both the conduction band and the valence bandof PdO nanoparticles lie between those of TiO
2; thus the
photogenerated electrons from TiO2conduction band can
easily be channeled to the PdO conduction band while theholes from the TiO
2valence band can also be partially
trapped in the PdO valence band before scavenging watermolecules to generate highly reactive OH radicals.Therefore,the photo induced electron transfer that occurs from TiO
2
to PdO nanoparticles prolongs the lifetime of electron-holepairs. It is also widely accepted that PdO is a more effectiveelectron acceptor than Pd, which further contributes to itseffectiveness in enhanced photocatalytic activity. Finally, evenwhen electrons and holes become trapped at the surface, theymay fail to induce the surface reaction.These factors, togetherwith the normal mass transfer limitations and losses due toimperfect mixing and uncertainties in photon fluxes, have aneffect on the observed photodegradation rates [44].
Irradiation of TiO2with UV light generates conduction
band electrons (e−) and valence band holes (h+) (Figure 9).The holes can scavenge surface hydroxyl ions or water toproduce hydroxyl radicals (OH∙), while electrons can reactwith adsorbed molecular oxygen yielding superoxide anionradicals (O
2
∙). The superoxide anion radicals can act as
oxidising agents or as additional sources of hydroxyl radicalswhen they react with water molecules.Theoretically, the pure
10 Journal of Nanomaterials
CB
VB
VisUV
Base metal/PGM trap sites
EY Degradation products
EY
O2
e− e−
h+
h+
N 2p
H2O/OH−
H2O
Reco
mbi
natio
n
O2∙
OH∙
OH∙
Figure 9: Schematic illustration of the proposed spatial distribution of electrons/holes and the generation of free radicals for EY degradationin a codoped TiO
2system.
TiO2cannot be excited by visible light because of its high
band gap energy (3.2 eV). Introduction of nitrogen createsenergy states closer to the valence band within the TiO
2
band gap. This reduces the band gap of the N doped TiO2,
extending the absorption edge well into the visible region.The excited electrons can quickly recombine with the holes,losing energy in the form of heat. However, in the presenceof metals, which also form energy states within the TiO
2
band gap, a Schottky barrier is formed at the semiconductor-metal interface causing some band bending. This electrondeficiency region acts as an electron sink, trapping theelectrons and prolonging the lifetime of holes. The overalleffect is retardation of charge carrier recombination ratecoupled with preferential formation of the highly oxidativehydroxyl radicals that can mineralise organic compoundssuch as dyes to harmless products, water, and carbon dioxide[34].
4. Conclusion
Nitrogen, base metal and nitrogen, PGM codoped TiO2
nanoparticles were successfully synthesised by a simple mod-ified sol-gel technique and evaluated for their visible lightphotocatalytic activities. The materials consisted mainly ofthe anatase phase after calcination at 500∘C. Codoping led toa red shift in the absorption edge of thematerials and this wasconfirmed by the reduction in the band gaps. TEM analysisverified the presence of uniformly dispersed and very small(5 nm) PdO particles deposited on the TiO
2in N, Pd TiO
2.
Themetals in the other samplesweremost likely incorporatedinto the lattice of TiO
2as there was no visible evidence of
their presence from TEM analysis. The N, PMG codopedTiO2showed significantly enhanced photocatalytic activity
compared to the N, base metal codoped samples undervisible light irradiation. These results indicate that formationof a Schottky barrier at the metal-TiO
2interface creates
electron trap sites that act as electron sinks, prolongingthe lifetime of holes for enhanced photoactivity. This effectwas more pronounced for PGMs compared to base metals.While the use of PGMs (Pd and Os) as TiO
2dopants in
wastewater treatment may prove uneconomical because oftheir high cost and scarcity, their catalytic effect proved tobe better than that of the cheaper and readily available basemetals in N, metal codoped TiO
2. Therefore, a compromise
may need to be considered between cost, availability, andefficiency in selecting the best TiO
2metal dopants for water
decontamination.
Conflict of Interests
The authors declare that there is no conflict of interestsregarding the publication of this paper.
Acknowledgments
Funding from DST/Mintek Nanotechnology InnovationCentre is appreciated.
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